The discovery and structure-activity relationships of nonpeptide, low molecular weight antagonists selective for the endothelin ETB receptor

The systematic modification of the ET_A selective N-(5-isoxazolyl)benzene-sulfonamide endothelin antagonists to give ET_B selective antagonists is reported. The reversal in selectivity was brought about by substitution of the 4-position with aryl and substituted aryl groups. Of all the aromatic substituents studied, the para-tolyl group gave rise to the most active and selective ET_B antagonist. Larger substituents caused a decrease in both ET_B activity and selectivity. A similar trend was observed by substitution at the 5-position of the N-(5-isoxazolyl)-2-thiophenesulfonamide ET_A receptor antagonists. The para-tolyl group was again found to be optimal for the ET_B activity and selectivity. The structural features that were found to be favorable for binding to the ET_B receptor, that is, the presence of a linear, conjugated π-system of definite shape and size, have been successfully incorporated into the design of ET_B selective polycyclic aromatic sulfonamides antagonists.     

Prediction of the conformational requirements for binding to the κ-opioid receptor and its subtypes. I. Novel α-helical cyclic peptides and their role in receptor selectivity

A conformational search of two similar κ-selective cyclic Dynorphin A (Dyn A) analogues is presented. Dyn A_1–11-NH₂( 1 ) and Dyn A_1–11-NH₂ ( 2 ) are not only highly potent κ-selective peptides but they also exhibit exceptional selectivity for κ receptors in the central (brain) vs. the peripheral (ileum) systems. Molecular mechanics systematic searching of the conformational preferences of the cyclic moieties of 1 and 2 produced 741 and 1003 starting ring structures, which were minimized at two dielectric constants of 2.0 and 80.0 in the AMBER force field. By rms superimposition, these low energy structures were grouped into conformational families for each ring system minimized at each dielectric. Comparison of the lowest energy structure of each of these families demonstrated that two (labeled A and B) were found as low energy ring systems for both 1 and 2 after minimization at either dielectric constant. These two structures are thus predicted to be the putative binding conformations for Dynorphin A at receptors in the brain. Interestingly, one of these putative binding structures exhibited an α-helical conformation in the disulfide bridged ring that has not been observed for small cyclic peptides of this nature before. Molecular dynamics simulation of the helical binding structures indicated that the helical configuration in 2 is lower in energy and is more confor-mationally stable than that of 1 . We correlate this with the increased selectivity and potency of 2 for κ receptors in the brain compared to the periphery, implying that this may be due to an α-helical conformation in the cyclized address or helical induction in the message sequence. © 1994 John Wiley & Sons, Inc.     

Biological and structural characteristics of the binding peptides from the sporozoite proteins essential for cell traversal (SPECT)-1 and -2

The sporozoite microneme proteins essential for cell traversal, SPECT-1 and SPECT-2, are considered attractive pre-erythrocytic immune targets due to the key role they play in crossing of the malaria parasite across the dermis and the liver sinusoidal wall, prior to invasion of hepatocytes. In this study, the sequences of SPECT-1 and SPECT-2 were mapped using 20 mer-long synthetic peptides to identify high-activity binding peptides (HABPs) to HeLa cells. 17 HABPs with enzyme sensitive bindings to HeLa cells were identified: 3 predominantly α-helical in SPECT-1, and 10 α-helical and 4 β-turns/random coils in SPECT-2. Immunofluorescence assays (IFA) with antibodies raised in rabbits against chemically synthesized B-cell epitopes suggests the presence of these two proteins in the micronemes and in sporozoite membrane. ¹H NMR studies showed that HABPs located in the membrane-attack complex/perforin (MACPF) domain of SPECT-2 share high similarity with the 3D structure of C8α. Altogether, the results highlight the potential of including HABPs from SPECT-1 and SPECT-2 as components of a fully effective multistage, multiepitopic, minimal subunit-based synthetic vaccine against Plasmodium falciparum malaria.     

Production of antimicrobial substances by Bacillus subtilis LFE-1, B. firmus HO-1 and B. licheniformis T6-5 isolated from an oil reservoir in Brazil

AIMS: Forty Bacillus strains isolated from a Brazilian oil reservoir were tested against each other to select strains producing antimicrobial substances (AMS). Three strains, Bacillus subtilis (LFE-1), Bacillus firmus (H2O-1) and Bacillus licheniformis (T6-5), were selected due to their ability to inhibit more than 65% of the Bacillus strains tested. These three strains were also investigated for their capability to inhibit sulphate-reducing bacteria (SRB). Furthermore, physiological and biochemical characteristics of the antimicrobial compounds produced by the selected strains were determined. METHODS AND RESULTS: Among the forty strains tested, 36 (90%) strains were able to inhibit at least one Bacillus strain used as indicator in plate assays and three of them (LFE-1, T6-5 and H2O-1) were able to inhibit 65, 70 and 97.5% of the 40 strains studied here respectively. Clear zones of inhibition were observed when H2O-1 was tested against SRB-containing consortium T6-lab and Desulfovibrio alaskensis strain NCIMB 13491, while strain T6-5 was able to inhibit only the D. alaskensis strain. The three substances showed to be insensitive to different enzymes and chemicals, were heat stable and the substances produced by strains T6-5 and H2O-1 were active over a wide pH range. CONCLUSIONS: Three different AMS produced by Bacillus strains from an oil reservoir, two of them with activity against SRB, are presented here. SIGNIFICANCE AND IMPACT OF THE STUDY: The preliminary characterization of these AMS points to their potential use as biocides in the petroleum industry for controlling problems associated with SRB.     

Modification of agonist binding moiety in hybrid derivative 5/7-{[2-(4-aryl-piperazin-1-yl)-ethyl]-propyl-amino}-5,6,7,8-tetrahydro-naphthalen-1-ol/-2-amino versions: Impact on functional activity and selectivity for dopamine D2/D3 receptors

The goal of the present study was to explore, in our previously developed hybrid template, the effect of introduction of additional heterocyclic rings (mimicking catechol hydroxyl groups as bioisosteric replacement) on selectivity and affinity for the D₃ versus D₂ receptor. In addition, we wanted to explore the effect of derivatization of functional groups of the agonist binding moiety in compounds developed by us earlier from the hybrid template. Binding affinity (K_i) of the new compounds was measured with tritiated spiperone as the radioligand and HEK-293 cells expressing either D₂ or D₃ receptors. Functional activity of selected compounds was assessed in the GTPγS binding assay. In the imidazole series, compound 10a exhibited the highest D₃ affinity whereas the indole derivative 13 exhibited similar high D₃ affinity. Functionalization of the amino group in agonist (+)-9d with different sulfonamides derivatives improved the D₃ affinity significantly with (+)-14f exhibiting the highest affinity. However, functionalization of the hydroxyl and amino groups of 15 and (+)-9d, known agonist and partial agonist, to sulfonate ester and amide in general modulated the affinity. In both cases loss of agonist potency resulted from such derivatization.     

Design and synthesis of novel nonpolar host peptides for the determination of the 310- and α-helix compatibilities of α-amino acid buildig blocks: An assessment of α,α-disubstituted glycines

The present work describes three novel nonpolar host peptide sequences that provide a ready assessment of the 3₁₀- and α-helix compatibilities of natural and unnatural amino acids at different positions of small- to medium-size peptides. The unpolar peptides containing Ala, Aib, and a C-terminal p-iodoanilide group were designed in such a way that the peptides could be rapidly assembled in a modular fashion, were highly soluble in solvent mixtures of triflouroethanol and H₂O for CD- and two-dimensional (2D) nmr spectroscopic analyses, and showed excellent crystallinity suited for x-ray structure analysis. To validate our approach we synthesized 9-mer peptides 79a–96 (Table IV), 12-mer peptides 99–110c (Table V), and 10-mer peptides 120a–125d and 129–133 (Table VI and Scheme 8) incorporating a series of optically pure cyclic and open-chain (R)- and (S)-α,α-disubstituted glycines 1–10 (Figure 2). These amino acids are known to significantly modulate the conformations of small peptides. Based on x-ray structures of 9-mers 79a, 80, and 87 (Figures 4–7), 10-mers 124c, 131, and 132 (Figures 9–12), and 12-mer peptide 102b (Figure 13), CD spectra of all peptides recorded in acidic, neutral, and basic media and detailed 2D-nmr analyses of 9-mer peptide 86 and 12-mer 102b, several interesting conformational observations were made. Especially interesting results were obtained using the convex constraint CD analysis proposed by Fasman on 9-mer peptides 79a–d, 80, 81, 86, and 87, which allowed us to determine the relative content of 3₁₀- and α-helical conformations. These results were fully supported by the corresponding x-ray and 2D-nmr analyses. As a striking example we found that the (S)- and (R)-β-tetralin derived amino acids (R)- and (S)-1 show excellent α-helix stabilisation, more pronounced than Aib and Ala. These novel reference peptide sequences should help establish a scale for natural and unnatural amino acids concerning their intrinsic 3₁₀- and α-helix compatibilities at different positions of medium-sized peptides and thus improve our understanding in the folding processes of peptides. © 1997 John Wiley & Sons, Inc. Biopoly 42: 575–626, 1997     

Computationally‐predicted CB1 cannabinoid receptor mutants show distinct patterns of salt‐bridges that correlate with their level of constitutive activity reflected in G protein coupling levels,thermal stability,and ligand binding

The cannabinoid receptor 1 (CB1), a member of the class A G‐protein‐coupled receptor (GPCR) family, possesses an observable level of constitutive activity. Its activation mechanism, however, has yet to be elucidated. Previously we discovered dramatic changes in CB1 activity due to single mutations; T3.46A, which made the receptor inactive, and T3.46I and L3.43A, which made it essentially fully constitutively active. Our subsequent prediction of the structures of these mutant receptors indicated that these changes in activity are explained in terms of the pattern of salt‐bridges in the receptor region involving transmembrane domains 2, 3, 5, and 6. Here we identified key salt‐bridges, R2.37 + D6.30 and D2.63 + K3.28, critical for CB1 inactive and active states, respectively, and generated new mutant receptors that we predicted would change CB1 activity by either precluding or promoting these interactions. We find that breaking the R2.37 + D6.30 salt‐bridge resulted in substantial increase in G‐protein coupling activity and reduced thermal stability relative to the wild‐type reflecting the changes in constitutive activity from inactive to active. In contrast, breaking the D2.63 + K3.28 salt‐bridge produced the opposite profile suggesting this interaction is critical for the receptor activation. Thus, we demonstrate an excellent correlation with the predicted pattern of key salt‐bridges and experimental levels of activity and conformational flexibility. These results are also consistent with the extended ternary complex model with respect to shifts in agonist and inverse agonist affinity and provide a powerful framework for understanding the molecular basis for the multiple stages of CB1 activation and that of other GPCRs in general. Proteins 2013; 81:1304–1317. © 2013 Wiley Periodicals, Inc.     

C<Subscript>1</Subscript>-/C<Subscript>2</Subscript>-aromatic-imino-glyco-conjugates: experimental and computational studies of binding,inhibition and docking aspects towards glycosidases isolated from soybean and jack bean

Several C₁-imino conjugates of d-galactose, d-lactose and d-ribose, where the nitrogen center was substituted by the salicylidene or naphthylidene, were synthesized and characterized. Similar C₂-imino conjugates of d-glucose have also been synthesized. All the glyco-imino-conjugates, which are transition state analogues, exhibited 100% inhibition of the activity towards glycosidases extracted from soybean and jack bean meal. Among these, a galactosyl-napthyl-imine-conjugate (1c) showed 50% inhibition of the activity of pure α-mannosidase from jack bean at 22 ± 2.5 μM, and a ribosyl-naphthyl-imine-conjugate (3c) showed at 31 ± 5.5 μM and hence these conjugates are potent inhibitors of glycosidases. The kinetic studies suggested non-competitive inhibition by these conjugates. The studies are also suggestive of the involvement of aromatic, imine and carbohydrate moieties of the glyco-imino-conjugates in the effective inhibition. The binding of glyco-imino-conjugate has been established by extensive studies carried out using fluorescence emission and isothermal titration calorimetry. The conformational changes resulted in the enzyme upon interaction of these derivatives has been established by studying the fluorescence quench of the enzyme by KI as well as from the secondary structural changes noticed in CD spectra. All these studies revealed the difference in the binding strengths of the naphthylidene vs. salicylidene as well as galactosyl vs. lactosyl moieties present in these conjugates. The differential inhibition of these glyco-conjugates has been addressed by quantifying the specific interactions present between the glyco-conjugates and the enzyme by using rigid docking studies. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.